Pedicle screw assembly with inclined surface seat

ABSTRACT

A bone stabilizer assembly includes a fixation element, a coupling element, and a compression nut. The fixation element is adapted to engage a bone and having a head portion and shank portion. The coupling element has an internal bore sized to receive the shank portion of the fixation element and a pyramid-shaped seat for supporting the head portion of the fixation element. The coupling element is adapted to receive a stabilizer rod. The compression nut is engagable with the coupling element and is adapted to rotatingly move distally into the coupling element to translate a force to the head portion through the rod and the saddle such that the head portion is forced against the seat of the coupling element to prevent relative movement between the fixation element and the coupling element.

REFERENCE TO PRIORITY DOCUMENT

This application is a division of and claims priority to co-pending U.S. patent application Ser. No. 11/777,945, titled “PEDICLE SCREW ASSEMBLY WITH INCLINED SURFACE SEAT,” filed Jul. 13, 2007, now U.S. Pat. No. 8,137,387, which in turn claims priority to U.S. Provisional Patent Application Ser. No. 60/831,094 filed Jul. 14, 2006. Priority of the aforementioned filing date is hereby claimed and the disclosures of the aforementioned co-pending Patent Application and Provisional Patent Application are hereby incorporated by reference in their entirety.

BACKGROUND

This disclosure is directed at skeletal bone fixation systems, and more particularly to a fixation assembly for vertebrae of a spinal column.

Spinal fixation systems are used to secure sections of the spinal column, such as vertebral bodies, into a fixed position to correct spinal injuries and defects. Internal fixation is used most frequently in the spine in conjunction with vertebral fusion, and also for the manipulation of the spine to correct spinal deformities. A typical spinal fixation assembly includes a fixation device, such as a screw or hook, that can be attached to a portion of a first vertebral body. The screw can be coupled to a stabilization member, such as an elongate rod, that can be linked to one or more additional vertebral bodies using additional screws.

Pursuant to a general process, two or more bone screws and/or hooks are secured to a vertebral body that is to be stabilized. After the screws are secured to the vertebral bodies, the screws are coupled to a spinal stabilization rod that restricts movement of the stabilized vertebra. It is important that the screws have a secure coupling with the spinal stabilization rod in order to prevent movement of the rod relative to the screw after placement.

In several available pedicle screw systems, a tulip-like coupling element with opposing upright arms or walls is used to secure the pedicle screw to the rod. The coupling element and pedicle screw are configured to be coupled to an elongate stabilizer, such as a rod, that is positioned above the head of the pedicle screw. A compression member, such as a compression nut, is configured to mate with the coupling element and provides a compressive force to the rod. The rod is then forced against the head of the pedicle screw, and that force is translated to the coupling element. Accordingly, the forces generated by the compression nut clamp the rod and pedicle screw head together within the coupling element.

One of the problems with this type of arrangement has been that the shape of the rod and the shape of the pedicle screw head are typically such that the amount of surface area contact between the two is limited. Rods are usually cylindrical and pedicle screw heads are usually either flat or hemispherical. The resulting contact area is relatively small, increasing the potential for slippage and failure in the pedicle screw system.

Another problem is that the upright legs or walls of the coupling element can experience splaying after implantation. Significant splaying of the arms generally results in failure of the coupling element, since the compression member or nut can no longer be retained in the coupling element to clamp the rod against the pedicle screw head. As a result, the rod is free to move relative to the coupling element, causing a failure that reduces or eliminates the effectiveness of the pedicle screw system.

Yet another problem is that the forces exerted on the coupling element can cause minute movement or rotation in the compression nut. As a result, the clamping force on the rod is reduced, potentially causing a failure in the pedicle screw system that can reduce or eliminate the effectiveness of the system.

Pedicle screw implantation procedures are costly, risky and result in painful and lengthy recovery for the patient. Thus, it is important that multiple surgeries to resolve failures in the implants be avoided. Furthermore, it can be a tedious process to position the screws on the vertebral bodies and to interconnect them with the stabilizing rod. Thus, it is desirable that the screws be easily attached to the rods and that, once attached, the coupling between the screw and rod be secure and not prone to failure. In view of the foregoing, there is a need for improved pedicle screw systems.

SUMMARY

Disclosed are bone stabilization assemblies for use in skeletal systems. In one aspect, a bone stabilizer assembly includes a fixation element, a coupling element, a saddle, a compression nut, and retention means for retaining the saddle in the coupling element in a floating configuration that permits a predetermined amount of movement between the saddle and the coupling element. The fixation element is adapted to engage a bone and has a head portion and shank portion. The coupling element has an internal bore sized to receive the shank portion of the fixation element and a seat adapted to support the head portion of the fixation element. The coupling element is also adapted to receive a stabilizer rod. The saddle is movably mounted in the coupling element below the stabilizer rod when the stabilizer rod is in the coupling element. The compression nut is engagable with the coupling element. The compression nut is adapted to rotatingly move distally into the coupling element to translate a force to the head portion through the rod and the saddle such that the head portion is forced against the seat of the coupling element to prevent relative movement between the fixation element and the coupling element.

In another aspect, a bone stabilizer assembly includes a fixation element, a coupling element, and a saddle. The fixation element is adapted to engage a bone and has a head portion and shank portion. The coupling element has an internal bore sized to receive the shank portion of the fixation element and a seat adapted to support the head portion of the fixation element. The coupling element further includes a pair of opposed walls separated by a stabilizer rod-receiving channel. Inner surfaces of the opposed walls include inner threads for mating with a compression nut and opposing indentations located below the inner threads. The saddle is movably mounted in the coupling element below the stabilizer rod when the stabilizer rod is in the coupling element. The saddle includes a pair of opposed walls separated by a rod-receiving region. Outer surfaces of the opposed walls include opposing protrusions that extend laterally from the walls. The protrusions are adapted to engage the opposing indentations in the opposed walls of the coupling element so as to retain the saddle within the coupling element when the stabilizer rod is disengaged from the coupling element.

In another aspect, a bone stabilizer assembly includes a coupling element and a compression nut. The coupling element includes a plurality of wall sections defining a longitudinal bore. The coupling element also includes a transverse channel substantially perpendicular to the bore. The compression nut includes a substantially cylindrical engagement portion having a longitudinal axis. A thread is formed on the engagement portion so that the engagement portion is adapted to be threadedly engaged within the bore to the wall sections. The thread has a profile that has a rotation stiffening component and an anti-splay component. The rotation stiffening component and the anti-splay component are integrated.

In another aspect, a bone stabilizer assembly includes a coupling element, and a compression nut. The coupling element includes a plurality of wall sections defining a longitudinal bore and a transverse channel substantially perpendicular to the bore. The compression nut includes a substantially cylindrical engagement portion having a longitudinal axis and a thread formed on the engagement portion so that the engagement portion is adapted to be threadedly engaged within the bore to the wall sections. The thread is sloped in a distal direction from a root of the thread to a crest of the thread.

In another aspect, a bone stabilizer assembly includes a fixation element, a coupling element, and a compression nut. The fixation element is adapted to engage a bone and having a head portion and shank portion. The coupling element has an internal bore sized to receive the shank portion of the fixation element and a conical seat for supporting the head portion of the fixation element. The coupling element is adapted to receive a stabilizer rod. The compression nut is engagable with the coupling element and is adapted to rotatingly move distally into the coupling element to translate a force to the head portion through the rod such that the head portion is forced against the seat of the coupling element to prevent relative movement between the fixation element and the coupling element.

In another aspect, a bone stabilizer assembly includes a fixation element, a coupling element, and a compression nut. The fixation element is adapted to engage a bone and having a head portion and shank portion. The coupling element has an internal bore sized to receive the shank portion of the fixation element and a pyramid-shaped seat for supporting the head portion of the fixation element. The coupling element is adapted to receive a stabilizer rod. The compression nut is engagable with the coupling element and is adapted to rotatingly move distally into the coupling element to translate a force to the head portion through the rod and the saddle such that the head portion is forced against the seat of the coupling element to prevent relative movement between the fixation element and the coupling element.

The details of one or more embodiments are set forth in the accompanying drawings and the description below. Other features, objects, and advantages will be apparent from the description and drawings, and from the claims.

DESCRIPTION OF DRAWINGS

FIG. 1 a is an illustration of a human vertebral column.

FIG. 1 b is a superior view of a typical human vertebra.

FIG. 1 c is a lateral view of the vertebra depicted in FIG. 1 b.

FIG. 2 is an illustration of a set of pedicle screws implanted into a human vertebral column

FIG. 3 shows an exploded view of a bone fixation assembly according to one embodiment.

FIG. 4 shows a cross-sectional view of the bone fixation assembly depicted in FIG. 3.

FIG. 5 a shows a cross-sectional view of a bone fixation assembly according to another embodiment.

FIG. 5 b is a magnified view of region 5 b depicted in FIG. 5 a.

FIG. 6 a is a side view of the bottom saddle depicted in FIGS. 3, 4 and 5.

FIG. 6 b is a perspective view of the bottom saddle depicted in FIGS. 3, 4 and 5.

FIG. 7 is a side elevation view of the bottom saddle depicted in FIGS. 6 a and 6 b as it is loaded into a bone fixation assembly.

FIG. 8 a shows a cross-sectional view of a bone fixation assembly according to another embodiment.

FIG. 8 b is a magnified view of region 8 b depicted in FIG. 8 a.

FIG. 9 shows an exploded view of the bone fixation assembly depicted in FIG. 8.

FIGS. 10 a-10 d show various views of the saddle depicted in the bone fixation assembly depicted in FIGS. 8 and 9.

FIG. 11 is a perspective view of the coupling element depicted in the bone fixation assembly depicted in FIGS. 8 and 9.

FIG. 12 a is a cross-sectional view of a bone fixation assembly according to another embodiment.

FIG. 12 b is a magnified view of region 12 b depicted in FIG. 12 a.

FIG. 13 a is a cross-sectional view of a bone fixation assembly according to another embodiment.

FIG. 13 b is a magnified view of region 13 b depicted in FIG. 13 a.

FIG. 14 a is a side view of the saddle depicted in the bone fixation assembly depicted in FIGS. 13 a and 13 b.

FIG. 14 b is a perspective view of the saddle depicted in FIG. 14 a.

FIG. 15 a is a cross-sectional view of a bone fixation assembly according to another embodiment.

FIG. 15 b is a cross-sectional view of the external threads of the compression nut depicted in FIG. 15 a.

FIG. 15 c is a cross-sectional view of the internal threads of the coupling element depicted in FIG. 15 a.

FIG. 16 is a cross-sectional view of a compression element of a bone fixation assembly according to one embodiment.

FIG. 17 a is a cross-sectional view of a compression element of a bone fixation assembly according to another embodiment.

FIG. 17 b is a cross-sectional view of the external threads of the compression nut depicted in FIG. 17 a.

FIG. 17 c is a cross-sectional view of the internal threads of the coupling element depicted in FIG. 17 a.

FIG. 18 a is a cross-sectional exploded view of a compression nut and top saddle according to one embodiment.

FIG. 18 b is a cross-sectional view of the compression nut and top saddle depicted in FIG. 18 a.

FIG. 19 a is a cross-sectional exploded view of a compression nut and top saddle according to another embodiment.

FIG. 19 b is a cross-sectional view of the compression nut and top saddle depicted in FIG. 19 a.

FIG. 20 a shows a cross-sectional view of the bone fixation assembly according to another embodiment.

FIG. 20 b is a magnified view of region 20 b depicted in FIG. 20 a.

FIG. 20 c shows an exploded view of a coupling element according to one embodiment.

FIG. 21 a shows a cross-sectional view of the bone fixation assembly according to another embodiment.

FIG. 21 b is a magnified view of region 21 b depicted in FIG. 21 a.

FIG. 21 c shows a conically-shaped seat of the coupling element according to one embodiment.

FIG. 22 shows a pyramid-shaped seat of the coupling element according to one embodiment.

FIG. 23 a shows another pyramid-shaped seat of the coupling element.

FIG. 23 b shows another pyramid-shaped seat of the coupling element.

FIG. 24 shows another pyramid-shaped seat of the coupling element.

DETAILED DESCRIPTION

Before discussing the embodiments in detail, it may be helpful to first briefly review the basic devices and concepts used in orthopedic surgery, and particularly spine surgery. Bone stabilization assemblies are commonly used throughout the skeletal system to stabilize broken, fractured, diseased or deformed bones. In particular, pedicle screw systems are particularly well adapted for the fixation and manipulation of the bones of the vertebral column.

A vertebral pedicle is a dense stem-like structure that projects from the posterior of a vertebra. There are two pedicles per vertebra that connect to other structures (e.g. lamina, vertebral arch). The location of a pedicle P is illustrated in FIGS. 1 b and 1 c, which illustrate a typical vertebral column, a superior view of a typical vertebra, and a lateral view of a typical vertebra, respectively.

Bone screws have been used in spinal instrumentation since the 1960s. A pedicle screw is a particular type of bone screw designed for implantation into a vertebral pedicle. Monoaxial pedicle screws are still used quite often, but the current standard for implantation is a polyaxial pedicle screw made of titanium or titanium alloy. Titanium alloy is useful, because it is highly resistant to corrosion and fatigue, and is MRI compatible. The screw is threaded and the head is moveable, allowing it to swivel so as to defray vertebral stress. Polyaxial pedicle screw lengths range from about 30 mm to about 60 mm with diameters ranging from about 5.0 mm to about 8.5 mm.

Pedicle screws are used to correct deformity, and or to treat trauma. They can be used in instrumentation procedures to affix rods and plates to the spine. They can also be used to immobilize part of the spine to assist fusion by holding bony structures together. Although pedicle screws are most often used in the lumbar (lumbosacral) spine, they can be implanted in the thoracic and sacral vertebra. The surgeon uses fluoroscopy, conventional x-ray, and sometimes computer-assisted visualization to determine the depth and angle for screw placement. A receiving channel is drilled and the screw is inserted. The screws themselves do not fixate the spinal segment, but act as firm anchor points that can then be connected with a rod. As shown in FIG. 2, the screws are placed down the small bony tube created by the pedicle on each side of the vertebra, between the nerve roots. This allows the screws to grab into the bone of the vertebral body, giving them a solid hold on the vertebra. Once the screws are placed, one in each of the two pedicles of each vertebra, they are attached to metal rods that connect the screws together. The screws are placed at two or more consecutive spine segments (e.g., lumbar segment 5 and 6) and connected by the rods.

Generally, a poly-axial pedicle screw assembly, as described in more detail below, includes a tulip-like coupling element that can be coupled to a fixation element, such as, for example, a screw with a head that removably mates with the coupling element. The coupling element and fixation element are configured to be coupled to an elongate stabilizer, such as a rod, that is positioned between a top and a bottom saddle or between a compression member and bottom saddle. A compression member, such as a compression nut, is configured to mate with the coupling element and provides a compressive force to the top and bottom saddles or to the top of the elongate stabilizer rod to secure the elongate stabilizer rod therebetween. The top and bottom saddles are movably positioned within the coupling element such that they can gradually reposition into a secure engagement with the stabilizer as the compression member provides the compressive force.

Turning now to FIG. 3, a pedicle screw assembly includes an anchor 105 having a fixation element 110 that is removably coupled to a coupling element 115. The assembly further includes a stabilizer, such as an elongate rod 120, that can be compressively secured to the anchor 105, as described below. As described in detail below, the fixation element 110 can be coupled to a skeletal structure, such as a spinal vertebra by being drilled or screwed into, e.g., a pedicle of a vertebra. The coupling element 115 is used to couple the fixation element 110 to the stabilizer, which can be coupled to multiple fixation elements using additional coupling elements 115.

The fixation element or pedicle screw 110 can include, for example, an elongate screw having a threaded shank portion 205 with external threads that can be screwed into the bone structure, e.g., pedicle, of a vertebra. A head 210 is positioned at the upper end of the shank portion 205. The head 210 has a shape, such as a rounded shape, that is configured to mate with a correspondingly-shaped seat structure in the coupling element 115, as described below. A drive coupler, such as a drive cavity 215 is located within or on the head 210 of the fixation element 110. The drive cavity 215 has a shape that is configured to receive a device that can impart rotational movement to the fixation element 110 in order to screw the fixation element 110 into a bone structure. For example, the drive cavity 215 can have a hexagonal shape that is configured to receive therein an allen-style wrench.

It should be appreciated that the drive coupler need not be a cavity that mates with an allen-style wrench and that other types of drive couplers can be used. Moreover, the fixation element 110 can be in forms other than a shank, including, for example, a hook or clamp. Indeed, it should be appreciated that any structure or component configured for attachment to a bone structure can be used in place of the shank portion of the fixation element.

The coupling element 115 is configured to receive the fixation element 110 and the elongate rod 120. The coupling element 115 has an internal bore 305 that extends through the coupling element 115 along an axis A (the axis A is shown in FIGS. 3 and 4). The internal bore 305 is sized to receive at least the shank portion 205 of the fixation element therethrough. A pair of laterally-opposed, upwardly extending projections 310 is separated by the bore 305. The projections 310 have internal, threaded surfaces. In addition, a pair of U-shaped channels 315 extends through the coupling element for receiving therein the rod 120, which extends along an axis that is transverse to the axis A of the bore 305.

The upper ends of the projections 310 define an entry port that is sized to receive therein a compression nut 410, as described below. The compression nut 410 is described herein as having outer threads that are configured to mate with the inner threads on the opposed inner surfaces of the projections 310 of the coupling element 115. As described below, the entry port is sized and shaped to facilitate an easy entry of the compression nut 410 into or over the projections 310 of the coupling element.

A bottom saddle 320 and a top saddle 325 are configured to be positioned within the coupling element 115. The saddles each define a contact surface 330 (shown in FIG. 3) that has a contour selected to complement a contour of the outer surface of the rod 120. In one embodiment, the contact surfaces 330 have rounded contours that complement the rounded, outer surface of the rod 120. However, the contact surfaces 330 can have any shape or contour that complement the shape and contour of the rod 120. The contact surfaces 330 can also be roughed, serrated, ribbed, or otherwise finished to improve the frictional engagement between the saddles 320,325 and the rod. The rod 120 can also be correspondingly roughed, serrated, ribbed, or otherwise finished to further improve the frictional engagement between saddles 320, 325 and the rod.

The complementing shapes and contours between the contact surfaces 330 and rod 120 provide a maximum amount of contact area between the saddles 320, 325 and rod 120. For example, the rod 120 is shown having a rounded or convex outer surface. The contact surfaces 330 of the saddles 320, 325 are correspondingly rounded or concave such that the elongate rod 120 can fit snug between the saddles 320, 325 with the contact surfaces 330 of the saddles 320, 325 providing a wide area of contact with the outer surface of the elongate rod 120. It should be appreciated that the contour and shape of the contact surfaces 330 can be varied to match any contour of the outer surface of the elongate rod 120 or in any manner to maximize the amount of grip between the saddles and the elongate rod.

During assembly of the device, the shank portion 205 of the fixation element 110 is inserted through the bore 305 in the coupling element 115. The rounded head 210 abuts against and sits within a correspondingly-shaped seat 327 in the bottom of the coupling element 115 in a ball/socket manner, as shown in the cross-sectional view of FIG. 4. The seat 327 can have a rounded shape that is configured to provide a secure fit between the head 210 and the coupling element 115. Because the seat 327 is rounded, the head 210 can be rotated within the seat 327 to move the axis of the shank portion 205 to a desired orientation relative to the coupling element 115 and thereby provide a poly-axial configuration.

With the fixation element 110 seated in the coupling element 115, an operator can position the assembly relative to a bone structure such as a vertebra. When the device is fully assembled, the operator can couple a drive device (such as an Allen wrench) to the drive cavity 215 in the head 210 and rotate the fixation element 110 to drive the shank portion 205 into a vertebra or other bone structure. As mentioned, the bottom saddle 320 has an internal bore that is sized to receive therethrough the drive device to provide access to the head 210 of the fixation element 110.

The rod 120 is loaded into the coupling element 115 by inserting the rod downwardly between the projections 310 through the u-shaped channels 315, as shown in FIG. 3. As the rod 120 is moved downwardly into the coupling element 115, the outer surface of the rod 120 will eventually abut and sit against the corresponding rounded contact surface 330 of the bottom saddle 320. The compression nut 410 and attached upper saddle 325 are then threaded downward into the coupling element 115 by mating the external threads on the compression nut 410 with the internal threads on the projections 310 of the coupling element 115. The compression nut 410 can be threaded downward until the rod 120 is compressed between the top and bottom saddles, with the compression nut 410 providing the compression force.

As mentioned, the coupling element 115 has an entry port for the compression nut 410 that facilitates entry or coupling of the compression nut 410 into the coupling element 115. The entry port is defined by the upper edges of the projections 310. The entry port has a structure that guides the compression nut into a proper engagement with the coupling element 115. For example, one or more large chamfers 425 are located on the upper, inner edge of the projections 310 of the coupling element 115 to provide ease of entry for the compression nut 410 into the coupling element 115. In one embodiment, the chamfers 425 are angled with the angle being in the range of thirty degrees to sixty degrees relative to vertical axis A, although the angle can vary. The chamfers 425 guide the compression nut 410 into proper alignment with the coupling element 115 such that the threads on the compression nut properly engage the threads on the opposed projections 310 without any cross-threading.

The compression nut 410 is then threaded downwardly by repeatedly rotating the compression nut 410 about a 360 degree rotation. As the compression nut 410 lowers into the coupling element, the rounded contact surface 330 of the top saddle 325 abuts the rod 120 and compresses the rod 120 against the rounded contact surface 330 of the bottom saddle 320, as shown in FIG. 4. As mentioned the bottom saddle 320 has a floating arrangement with the coupling element 115 and the top saddle 325 is movable and rotatable relative to the compression nut 410. This permits the saddles to gradually reposition themselves into a secure purchase with the rod 120 as the compression nut 410 moves downward. The contact surfaces 330 of the saddles 320, 325 provide a continuous and maximized area of contact between the saddles 320, 325 and the rod 120 for a secure and tight fit therebetween.

Moreover, the top saddle 325 is shaped so that opposed wings or protrusions 329 are located on opposed sides of the top saddle 325 (see FIGS. 16-17). The opposed protrusions 329 are positioned on either side of the rod 120 so as to automatically guide the saddle 325 into alignment with the rod 120 as the saddle 325 lowers onto the rod. Because the top saddle 325 can freely rotate as the compression nut lowers onto the rod 120, the protrusions 329 will abut opposed sides of the rod 120 as the top saddle 325 is lowered into the coupling element 115. The top saddle 325 thus self-aligns into a secure engagement with the rod 120 as the top saddle 325 is lowered onto the rod 120.

In one embodiment, the protrusions 329 of the top saddle are formed by a concave contour of the top saddle contact surface 330. It should be appreciated that the protrusions 329 need not be formed from curved surfaces, but can also be formed from straight surfaces. Moreover, the protrusions 329 need not be formed from a continuous, elongated surface, but can rather comprise one or more discrete protrusions, such as spikes, that extend downwardly from the top saddle 325.

As the compression nut 410 is threaded downward, the downward force of the compression nut 410 is transferred to the bottom saddle 320 via the top saddle 325 and the rod 120. This causes the bottom saddle 320 to also move downward so as to press downward against the head 210 of the fixation element 110. The head 210 is thereby pressed downward into the seat 327 in a fixed orientation. In this manner, the position of the fixation element 110 relative to the coupling element 115 is fixed. That is, the head 210 of the fixation element 110 is pressed downward into the seat 327 of the coupling element 115 with a force sufficient to lock the position of the head 210 relative to the coupling element 115.

The compression nut 410 can be tightened to provide a sufficient downward force that locks the positions of the saddles 320, 325 relative to the coupling element 115 and the elongate rod 120. The compression nut 410 thereby provides a downward force that locks the relative positions of the elongate rod 120, saddles 320, 325, coupling element 115, and fixation element 110. After this is complete, the upper portion of the opposed projections 310 of the coupling element can be snapped off at a predetermined location along the length of the projections 310.

As discussed, inner threads are located on the opposed inner faces of the projections 310. The threads extend downwardly along the projections 310 to a depth that is sufficient to provide secure engagement between the threads on the projections 310 and the threads on the compression nut 410 when the compression nut 410 is fully tightened. It should be appreciated that the threads do not have to extend to a depth below the upper surface (identified by line U in FIG. 4) of the rod 120 when the rod 120 is positioned in the coupling element 115. In one embodiment, the threads extend to a depth that is above the upper surface (identified by line U) of the rod 120. The top saddle 325 provides a spacing between the rod 120 and the compression nut 410, which permits such thread depth.

As shown in FIGS. 3, 6 a and 6 b, the bottom saddle 320 has an internal bore 316 that axially aligns with the bore 305 in the coupling element 115 when the bottom saddle 320 is placed in the coupling element 115. The bottom saddle 320 has a cylindrical outer surface 326 forming a pair of opposed walls 321 separated by the internal bore 316 and a rod-receiving region 323. Outer surfaces of the opposed walls 321 include opposing projections 335 that extend laterally from the walls 321. Each of the projections 335 aligns with a corresponding hole or aperture 340 (shown in FIGS. 3 and 4) that extends through the coupling element 115. The opposed walls are generally perpendicular to the base 324 of the saddle 320, as indicated by angle α shown in FIG. 6A.

As shown in FIG. 4, the bottom saddle 320 is secured within the coupling element 115 by positioning the saddle between the projections 310 such that each projection 335 in the bottom saddle 320 is inserted into a corresponding aperture 340 in the coupling element 115. The bottom saddle 320 is inserted into the coupling element 115 by forcing the saddle 320 down through the projections 310 of the coupling element. The distance X, depicted in FIG. 6 a, represents the distance between the outer ends 336 of the projections 335. Distance Y, depicted in FIG. 4, represents the distance between the inner surfaces 311 of the projections 310 of the coupling element 115. Distance X is slightly greater than distance Y. Therefore, saddle 320 must be inserted into the coupling element 115 by forcing it downward through the projections 310 against which the projections 335 will scrape. Once the saddle 320 has been pushed down far enough inside the coupling element 115 that the projections 335 line up with the corresponding apertures 340, the projections 335 will pop into the apertures 340. The projections 335 are shaped to facilitate insertion and retention of the saddle 320 within the coupling element 115. As shown in FIGS. 6 a and 6 b, the projections 335 have a flat or horizontal proximal surface 338, a rounded side or lateral surface 336, and an angled or ramped distal surface 337. The flat proximal surface 338 prevents the saddle 320 from sliding out of the coupling element 115 in the proximal direction. The angled or ramped distal surface 337 allows the saddle to be guided into the coupling element. The opposed walls 321 can be slightly flexible so that during insertion the walls 321 flex inward toward each other to allow the saddle 320 to be pushed down into the coupling element 115. Once the projections 335 of the saddle 320 reach the apertures 340 of the coupling element, the walls 321 flex back to their natural position and the projections 335 pop into the apertures 340.

The apertures 340 can be round, rectangular, square, oval or any other shape that can receive the projections 335 in a manner that allows the saddle 320 to float in the coupling element 115. Likewise, rather than the shape described above, the projections 335 can be cylindrical, conical, block (rectangular or square), or any other shape that fits within the apertures 340 in a manner that allows the saddle to float in the coupling element 115.

Alternatively, the saddle 320 can be inserted into the coupling element 115 in the manner shown in FIG. 7. The saddle 320 is first rotated so that the walls 321 are aligned with the U-shaped channels 315 rather than the projections 310 of the coupling element 115. The diameter of the cylindrical outer surface 326 of the saddle 320 is slightly smaller than the distance Y between the inner surfaces 311 of the projections 310 of the coupling element 115 so that the saddle 320 slides freely into the coupling element 115 without any significant frictional engagement between the saddle 320 and coupling element 115. Once the projections 335 are at the same level as the apertures 340, the saddle 320 is rotated about 90° until the projections 335 pop into the apertures 340. As the saddle is rotated, the projections 335 will scrape against the inner surfaces 311 of the projections 310. The rounded lateral surface 336 of the projections 335 facilitate the rotation of the saddle 320.

As best seen in FIG. 4, the diameter of the aperture 340 can be greater than the distance between the proximal end 338 of the projection 335 and the distal end 337 of the projection 335 by between about 1.0 mm and about 3 mm. In one embodiment, the diameter of the aperture 340 is about 1.0 mm greater than the distance between the proximal end 338 of the projection 335 and the distal end 337 of the projection 335, allowing about 1.0 mm of play between the bottom saddle 320 and the coupling element 115. The diameter of the cylindrical outer surface 326 of the bottom saddle is also less than distance Y between the projections 310. These dimensions permit the bottom saddle 320 to “float” in the coupling element 115 such that the position and the orientation of the bottom saddle 320 can be varied slightly. That is, the bottom saddle 320 can be moved slightly upward or downward and from side to side when mounted in the coupling element 115. The bottom saddle 320 can also rotate slightly when mounted in the coupling element 115. Thus, the bottom saddle 320 can movingly adjust into a secure engagement with the elongate rod 120 when compressed against the elongate rod 120 during assembly, as described below. It can also movingly adjust into a secure engagement with the head portion 210 of the fixation element 110 when pushed down against the head portion 210 by the elongate rod 120.

In another embodiment, as shown in FIGS. 5 a and 5 b, the coupling element 115 has a channel 440 rather than apertures 340. Each of the projections 310 of the coupling element 115 has a channel 440 bored into it, and the channels 440 are aligned with one another and face one another as shown in FIG. 5 a. The projections 435 of the saddle 320 can be mated with the channels 440 so as to retain the bottom saddle 320 within the coupling element 115. The saddle 320 shown in FIGS. 5 a and 5 b can have the same projections 335 as shown in FIGS. 6 a and 6 b, or it can have square or rectangular block projections 435 as shown in FIGS. 5 a and 5 b.

As shown in closer detail in FIG. 5 b, the lateral ends 436 of the saddle 320 do not make contact with the lateral surface 441 of the channel 440. In other words the distance between the lateral surfaces 441 of the two projections 310 is greater than the distance between the lateral ends 436 of the projections 435 of the bottom saddle 320. Thus, there is no axial force or frictional engagement between the projections 435 and the channels 440. This permits some play between the bottom saddle 320 and the coupling element 115. In addition, the height of the projections 435 (i.e., the distance between the proximal surface 438 and distal surface 437 of the projections 435) is between about 1.0 mm and 3.0 mm less than the height of the channels 440 (i.e., the distance between the proximal inner surface 448 and distal inner surface 447 of the channels 440). In one embodiment, the height of the channels 440 is about 1.0 mm greater than the height of the projections 435, allowing about 1.0 mm of play between the bottom saddle 320 and the coupling element 115. The diameter of the cylindrical outer surface 326 of the bottom saddle is also less than distance Y between the projections 310. These dimensions permit the bottom saddle 320 to “float” in the coupling element 115 such that the position and the orientation of the bottom saddle 320 can be varied slightly. That is, the bottom saddle 320 can be moved slightly upward or downward and from side to side when mounted in the coupling element 115. The bottom saddle 320 can also rotate slightly when mounted in the coupling element 115. Thus, the bottom saddle 320 can movingly adjust into a secure engagement with the elongate rod 120 when compressed against the elongate rod 120 during assembly, as described below. It can also movingly adjust into a secure engagement with the head portion 210 of the fixation element 110 when pushed down against the head portion 210 by the elongate rod 120.

The saddle 320 can be inserted into the coupling element 115 in a manner similar to that shown in FIG. 7. The saddle 320 is first rotated so that the walls 321 are aligned with the U-shaped channels 315 rather than the projections 310 of the coupling element 115. The diameter of the cylindrical outer surface 326 of the saddle 320 is slightly smaller than the distance Y between the inner surfaces 311 of the projections 310 of the coupling element 115 so that the saddle 320 slides freely into the coupling element 115 without any significant frictional engagement between the saddle 320 and coupling element 115. Once the projections 435 are at the same level as the channels 440, the saddle 320 is rotated until the projections 435 slide into the channels 440. The channels 440 can extend along the entire circumference or length of the inner surfaces 311 of the projections 435 so that the projections 435 slide into the channels 440 without running into or contacting the projections 435.

FIGS. 8-11 describe another embodiment, which differs from the other embodiments only with respect to the bottom saddle 520 and retention means for the bottom saddle 520 within the coupling element 115. The bottom saddle depicted in FIGS. 8-11 is designed to permit the opposed walls 521 to tilt toward one another in response to compression forces, and to spring back to their original or resting parallel orientation in the absence of compression forces.

As shown in FIGS. 10 a-10 d, the bottom saddle 520 has an internal bore 516 that axially aligns with the bore 305 in the coupling element 115 when the bottom saddle 520 is placed in the coupling element 115. The bottom saddle 520 has a cylindrical outer surface 526 forming a pair of opposed walls 521 separated by the internal bore 516 and a rod-receiving region 523. Opposed walls 521 are generally perpendicular to the base 524 of the bottom saddle 520, as indicated by angle α shown in FIG. 10A. Outer surfaces of the opposed walls 521 include opposing projections 535 that extend laterally from the walls 521. Each of the projections 535 aligns with a corresponding cavity 540 (shown in FIG. 11) that is carved into each of the projections 310 of the coupling element 115. The opposed walls 521 of the saddle 520 are connected to one another by a pair of flexible joints 580 that permit the opposing walls 521 to tilt toward one another in response to compression forces, and to spring back to their original or resting parallel orientation in the absence of compression forces. The flexible joints 580 are formed by a pair of keyhole slots 581 carved into the cylindrical portion 526 of the bottom saddle 520. The keyhole slots 581 are opposite each other and are each aligned about 90° away from each of the projections 535. Consequently, the flexible joints 580 are opposite each other and are each aligned about 90° away from each of the projections 535. The keyhole slots 581 and the flexible joints 580 permit the opposed walls 521 to be squeezed toward one another in response to a compressive force and to spring back into a resting parallel orientation in the absence of a compressive force.

As shown in FIG. 8, the bottom saddle 520 is secured within the coupling element 115 by positioning the saddle between the projections 310 such that each projection 535 in the bottom saddle 520 is inserted into a corresponding cavity 540 in the coupling element 115. The bottom saddle 520 is inserted into the coupling element 115 by forcing the saddle 520 down through the projections 310 of the coupling element. The distance X, depicted in FIG. 8 a, represents the distance between the lateral surface 536 of the projections 535. Distance Y, depicted in FIG. 8 a, represents the distance between the inner surfaces 311 of the projections 310 of the coupling element 115. Distance X is slightly greater than distance Y. Therefore, the saddle 520 must be inserted into the coupling element 115 by forcing it downward through the projections 310 against which the projections 535 will scrape. The opposed walls 521 of the saddle 520 can be squeezed toward one another because of the flexible joints 580 and keyhole slots 581 (shown in FIG. 10 b). Once the saddle 520 has been pushed down far enough inside the coupling element 115 that the projections 535 line up with the corresponding cavities 540, the projections 535 will pop into the cavities 540. The projections 535 are shaped to facilitate insertion and retention of the saddle 520 within the coupling element 115. As shown in FIGS. 10 c and 10 d, the projections 535 have a flat or horizontal proximal surface 538, a rounded side or lateral surface 536, and an angled or ramped distal surface 537 (alternatively, the distal surface 537 can be horizontal or flat). The flat proximal surface 538 prevents the saddle 520 from sliding out of the coupling element 115 in the proximal direction. The angled or ramped distal surface 537 allows the saddle to be guided into the coupling element 115. The opposed walls 521 are flexible so that during insertion the walls 521 flex inward toward each other to allow the saddle 520 to be pushed down into the coupling element 115. Once the projections 535 of the saddle 520 reach the cavities 540 of the coupling element 115, the walls 521 flex back to their natural or resting position and the projections 535 pop into the cavities 540.

The cavities 540 can be round, rectangular, square, oval or any other shape that can receive the projections 535 in a manner that allows the saddle 520 to float in the coupling element 115. Likewise, rather than the shape described above, the projections 535 can be cylindrical, conical, block (rectangular or square), or any other shape that fits within the cavities 540 in a manner that allows the saddle 520 to float in the coupling element 115.

Alternatively, the saddle 520 can be inserted into the coupling element 115 in the manner shown in FIG. 7. The saddle 520 is first rotated so that the walls 521 are aligned with the U-shaped channels 315 rather than the projections 310 of the coupling element 115. The diameter of the cylindrical portion 526 of the saddle 520 is slightly smaller than the distance Y between the inner surfaces 311 of the projections 310 of the coupling element 115 so that the saddle 520 slides freely into the coupling element 115 without any significant frictional engagement between the saddle 520 and coupling element 115. Once the projections 535 are at the same level as the cavities 540, the saddle 520 is rotated about 90° until the projections 535 pop into the cavities 540. As the saddle is rotated, the projections 535 will scrape against the inner surfaces 311 of the projections 310. The rounded lateral surface 536 of the projections 535 facilitate the rotation of the saddle 520.

As shown in closer detail in FIG. 5 b, the lateral ends 436 of the saddle 320 do not make contact with the lateral surface 441 of the cavities 440. In other words the distance between the lateral surfaces 441 of the two projections 310 is greater than the distance between the lateral ends 436 of the projections 435 of the bottom saddle 320. Thus, there is no axial force or frictional engagement between the projections 435 and the channels 440. This permits some play between the bottom saddle 320 and the coupling element 115. In addition, the height of the projections 435 (i.e., the distance between the proximal surface 438 and distal surface 437 of the projections 435) is between about 1.0 mm and 3.0 mm less than the height of the channels 440 (i.e., the distance between the proximal inner surface 448 and distal inner surface 447 of the channels 440). In one embodiment, the height of the channels 440 is about 1.0 mm greater than the height of the projections 435, allowing about 1.0 mm of play between the bottom saddle 320 and the coupling element 115. The diameter of the cylindrical portion 326 of the bottom saddle is also less than distance Y between the projections 310. These dimensions permit the bottom saddle 320 to “float” in the coupling element 115 such that the position and the orientation of the bottom saddle 320 can be varied slightly. That is, the bottom saddle 320 can be moved slightly upward or downward and from side to side when mounted in the coupling element 115. The bottom saddle 320 can also rotate slightly when mounted in the coupling element 115. Thus, the bottom saddle 320 can movingly adjust into a secure engagement with the elongate rod 120 when compressed against the elongate rod 120 during assembly, as described below. It can also movingly adjust into a secure engagement with the head portion 210 of the fixation element 110 when pushed down against the head portion 210 by the elongate rod 120.

Referring now to FIGS. 12 a and 12 b, the bottom saddle 520 is the same or substantially the same as bottom saddle 520 shown in FIGS. 8 a-10 d. The bottom saddle 520 is secured within the coupling element 115 by positioning the saddle between the projections 310 such that each projection 535 in the bottom saddle 520 is inserted into a corresponding cavity 940 in the coupling element 115. The bottom saddle 520 is inserted into the coupling element 115 by forcing the saddle 520 down through the projections 310 of the coupling element. The distance X, depicted in FIG. 12 a, represents the distance between the outer ends 436 of the projections 535. Distance T, depicted in FIG. 12 a, represents the distance between the inner surfaces 311 of the projections 310 of the coupling element 115. Distance X is slightly greater than distance T. Therefore, saddle 520 must be inserted into the coupling element 115 by forcing it downward through the projections 310 against which the projections 335 will scrape. The opposed walls 521 of the saddle 520 can be squeezed toward one another because of the flexible joints 580 and keyhole slots 581. Once the saddle 520 has been pushed down far enough inside the coupling element 115 that the projections 535 line up with the corresponding cavities or indentations 940, the projections 535 will pop into the cavities 940. The projections 535 are shaped to facilitate insertion and retention of the saddle 520 within the coupling element 115 as described with respect to FIGS. 10 c and 10 d above. The opposed walls 521 are flexible so that during insertion the walls 521 flex inward toward each other to allow the saddle 520 to be pushed down into the coupling element 115. Once the projections 535 of the saddle 520 reach the cavities or indentations 940 of the coupling element 115, the walls 521 flex back to their natural or resting position and the projections 535 pop into the cavities 940.

The cavities 940 are aligned with one another, but they are not parallel with one another. Instead, as shown in more detail in FIG. 12 b and further described below, the cavities 940 are sloped or ramped toward one another in the distal direction.

The cavities 940 each have a proximal region, which is near the top end of the coupling element 115, a middle region distal the proximal region, and a distal region, which is distal the middle region. The distance Z between the proximal regions of the cavities 940 is greater than the distance X between the outer ends 536 of the projections 535, and the distance X is greater than the distance Y between the distal regions of the cavities 940. The proximal region of the cavities 940 each includes a ridge with a drop-off as shown in FIG. 12 b. A middle region of the cavities 940, distal the proximal region, forms a ramp that is sloped inward toward a distal direction, wherein the proximal end of the ramp starts at the drop-off and a distal end of the ramp terminates in a distal region that joins the ramp to the inner surface 311 of the wall of the coupling element 115.

In the proximal regions of the cavities, because distance X is less than distance Z, the projections 535 do not make contact with the inner surface 941 of the cavities. Thus, there is no axial force or frictional engagement between the projections 535 and the inner surface 941 of the cavities 940 in the proximal region. This permits some play between the bottom saddle 520 and the coupling element 115 when the bottom saddle is in the proximal region of the cavities 940. In addition, the height of the projections 535 (i.e., the distance between the proximal surface 538 and distal surface 537 of the projections 535) is between about 1.0 mm and 3.0 mm less than the height of the proximal region of the cavities 940. In one embodiment, the height of the proximal region of the cavities 940 is about 1.0 mm greater than the height of the projections 535, allowing about 1.0 mm of play between the bottom saddle 520 and the coupling element 115 when the projections are situated in the proximal region of the cavities 940. The diameter of the cylindrical portion 526 of the bottom saddle is also less than distance Y between the projections 310. These dimensions permit the bottom saddle 520 to “float” in the coupling element 115 such that the position and the orientation of the bottom saddle 520 can be varied slightly while the projections 535 are situated in the proximal region of the cavities 940. That is, the bottom saddle 520 can be moved slightly upward or downward and from side to side when mounted in the coupling element 115 when the projections 535 are situated within the proximal region of the cavities 940. The bottom saddle 520 can also rotate slightly when mounted in the coupling element 115 when the projections 535 are situated within the proximal region of the cavities 940.

As the saddle 520 is forced downward in the distal direction, the distance between the inner surfaces 941, which are in opposite projections 310, becomes smaller because of the sloped ramps. At some point in the middle region of the cavities 940 the projections 535 make contact with the inner surfaces 941 of the cavities 940. As the saddle 520 is further forced in the distal direction, inward axial forces are exerted on the projections 535 and the walls 521 are squeezed into frictional engagement with the sloped ramps. The frictional engagement between the opposing projections 535 and the distal region of the opposing cavities 940 maintains the saddle 520 in frictional engagement with the head portion 210 of the fixation element 110 to prevent relative movement between the fixation element 110 and the coupling element 115 when the stabilizer rod is disengaged from the saddle 520 and the saddle 520 engages the fixation element 110. The fixation element 110 and the coupling element 115 are still manually movable relative to each other in opposition to the frictional engagement when the stabilizer rod is disengaged from the saddle.

FIGS. 13A-14B describe another embodiment, which differs from the previous embodiments only with respect to the bottom saddle 1220 and retention means for the bottom saddle 1220 within the coupling element 115. Like the bottom saddle shown in FIGS. 10A-10D, the bottom saddle 1220 depicted in FIGS. 13A-14B is designed to permit the opposed walls 1221 to tilt toward one another in response to compression forces, and to spring back to their original or resting parallel orientation in the absence of compression forces. The bottom saddle 1220, however, does not have projections that extend laterally from its opposed walls 1221. Instead, the outer surface 1226 of the opposed walls are at an angle α, as shown in detail in FIGS. 14A and 14B. In other words, the walls 1221 are not parallel to one another when the walls 1221 are in a resting or uncompressed state. Instead, they extend away from one another from bottom to top such that the angle α between the base 1224 of the bottom saddle 1220 and the outer surface of the walls 1226 is an obtuse angle or greater than 90° when the walls 1221 are in a resting or uncompressed state.

As with previous embodiments, the bottom saddle 1220 has an internal bore 1216 that axially aligns with the bore 305 in the coupling element 115 when the bottom saddle 1220 is placed in the coupling element 115. The bottom saddle 1220 has a frustoconical outer surface 1226 forming a pair of opposed walls 1221 separated by the internal bore 1216 and a rod-receiving region 1223. Outer surfaces of the opposed walls 1221 are angled toward one another as explained above. The opposed walls 1221 of the saddle 1220 are connected to one another by a pair of flexible joints 1280 that permit the opposing walls 1221 to tilt toward one another in response to compression forces, and to spring back to their original or resting parallel orientation in the absence of compression forces. The flexible joints 1280 are formed by a pair of keyhole slots 1281 carved into the frustoconical portion 1226 of the bottom saddle 1220. The keyhole slots 1281 are opposite each other. The keyhole slots 1281 and the flexible joints 1280 permit the opposed walls 1221 to be squeezed toward one another in response to a compressive force and to spring back into a parallel orientation in the absence of a compressive force.

As shown in FIG. 13 a, the bottom saddle 1220 is secured within the coupling element 115 by positioning the saddle between the projections 310 such that each of the walls 1221 of the bottom saddle is inserted into a corresponding retention region 1240 in the coupling element 115. The bottom saddle 1220 is inserted into the coupling element 115 by forcing the saddle 1220 down through the projections 310 of the coupling element. The distance X, depicted in FIG. 13 a, represents the distance between the outer surface 1226 of walls 1221 in the proximal region 1235 of the walls. Distance T, depicted in FIG. 13 a, represents the distance between the inner surfaces of the projections 310 of the coupling element 115 in a region proximal the retention region of the projections 310. The inner surfaces of the projections 310 in a region proximal the retention region form a cylinder, such that the walls are parallel to one another. Distance X is slightly greater than distance T. Therefore, the saddle 1220 must be inserted into the coupling element 115 by forcing it downward through the projections 310 against which the proximal region 1235 of the walls 1221 will scrape. The opposed walls 1221 of the saddle 1220 can be squeezed toward one another because of the flexible joints 1280 and keyhole slots 1281.

The retention region 1240 of the coupling element 115 begins at a proximal ridge 1241 that forms a pop-out with inner surfaces 311. The inner surfaces 311 are not parallel to one another. Instead, they are angled toward one another from a proximal to a distal direction. The inner surfaces 311 can be parallel with the opposed walls 1221 of the saddle such that opposed walls 1221 and inner surfaces 311 are at the same angle relative to the base 1224 of the saddle. For example, if the walls 1221 are at an angle of about 100° to the base 1224, then the inner surfaces 311 can also be at an angle of about 100° relative to the base 1224 of the saddle. Alternatively, the inner surfaces 311 can form a greater angle relative to the base 1224 than the opposed walls 1221, so that the opposed walls 1221 are not parallel to the base 1224. For example, if the walls 1221 are at an angle of about 100° to the base 1224, then the inner surfaces 311 can be at an angle of, e.g., 105° to the base. The retention regions 1240 of the projections 310 each have a proximal region, which is near the top end of the coupling element 115 just distal the ridge 1241, a middle region distal the proximal region, and a distal region, which is distal the middle region. The distance X between the proximal regions of the retention region 1240 is greater than the distance X between the outer proximal region 1235 of the walls 1221. Distance Z decreases in the distal direction, such that distance Y is less than distance X and distance Z. Thus, once the saddle 1220 has been pushed down far enough inside the coupling element 115 that it reaches the retention region 1240, proximal region 1235 of the walls 1221 will pop into the retention region 1240. In other words, once the proximal region 1235 of the walls 1221 of the saddle 1220 reach the retention region 1240 of the coupling element 115, the walls 1221 flex back to their natural or resting position and pop into the proximal region of the retention region 1240 where there is no compressive force against the walls 1221. Alternatively, the saddle 1220 can be inserted into the coupling element 115 in the manner shown in FIG. 7 and described above.

In the proximal regions of the retention regions 1240, because distance X is less than distance Z, the proximal region 1235 of the walls 1221 do not make contact with the inner surface 311 of the proximal regions of the retention regions 1240. Thus, there is no axial force or frictional engagement between the proximal region 1235 and the inner surface 311 of the retention region 1240. This permits some play between the bottom saddle 1220 and the coupling element 115 when the bottom saddle is in the proximal region of the retention region 1240. At about 1.0 mm below the ridge 1241, the distance between the inner surfaces 311, at distance Y, becomes equal to or less than the distance X, and the proximal region 1235 of the walls 1221 makes contact with the inner surface 311 of the retention regions 1240. This allows about 1.0 mm of play between the bottom saddle 1220 and the coupling element 115 when the proximal regions 1235 of the walls 1221 are situated in the proximal region of the retention region 1240. These dimensions permit the bottom saddle 1220 to “float” in the coupling element 115 such that the position and the orientation of the bottom saddle 1220 can be varied slightly while the proximal regions 1235 s are situated in the proximal region of the retention region 1240. That is, the bottom saddle 1220 can be moved slightly upward or downward and from side to side when mounted in the coupling element 115 when the proximal regions 1235 are situated within the proximal region of the retention region 1240. The bottom saddle 1220 can also rotate slightly when mounted in the coupling element 115 when the proximal regions 1235 are situated within the proximal region of the retention region 1240.

As the saddle 1220 is forced downward in the distal direction, the distance between the inner surfaces 311, which are opposite projections 310, becomes smaller because of the angled or sloped inner surfaces 311. At some point in the middle region of the retention region 1240, as explained above, the proximal regions 1235 make contact with the inner surfaces 311 of the retention region 1240. As the saddle 1220 is further forced in the distal direction, inward axial forces are exerted on the proximal regions 1235 of the walls 1221, and the walls 1221 are squeezed into frictional engagement with the sloped surfaces 311 of the retention region 1240. The frictional engagement between the proximal regions 1235 and the distal region of the retention region 1240 maintains the saddle 1220 in frictional engagement with the head portion 210 of the fixation element 110 to prevent relative movement between the fixation element 110 and the coupling element 115 when the stabilizer rod is disengaged from the saddle 1220 and the saddle 1220 engages the fixation element 110. The fixation element 110 and the coupling element 115 are still manually movable relative to each other in opposition to the frictional engagement when the stabilizer rod is disengaged from the saddle 1220.

Referring now to FIGS. 18 a and 18 b, the top saddle 325 is rotatingly mounted within a compression nut 410 that has outer threads that are configured to mate with the threads on the internal surface of the opposed projections 310 of the coupling element 115. In this regard, the top saddle 325 has an upper projection 316 that rotatingly mates with the compression nut 410 and permits the top saddle 325 to rotate and/or tilt relative to the compression nut 410 when attached thereto. The projection 316 has a lip portion 313 and a neck portion 314 connecting the lip portion to the saddle 325. The lip portion 313 of the projection 316 can be snapped into an opening 403 in the bottom of the compression nut 410. Once snapped in, the lip portion 313 rests against an angled ledge 404 formed in a bore just above the opening 403 of the compression nut 410. When attached, the top saddle 325 is positioned immediately below the compression nut 410 and can rotate relative to the compression nut 410.

In another embodiment shown in FIGS. 19 a and 19 b the top saddle 325 has a projection 316 with a neck portion 314 and an lip portion 313. The circumference of the neck portion 314 is greater than the circumference of the lip portion 313 and a step 312 is formed therebetween. The neck portion 314 and lip portion 313 are inserted through an opening 403 in the bottom of the compression nut 410 that leads to a chamber 406 for receiving a friction nut 800. The friction nut 800 is inserted through a top opening 405 in the compression nut 410. The friction nut 800 has a center bore 803 with a circumference that is slightly smaller than the circumference of the lip portion 313 of the projection 316 and significantly smaller than the circumference of the neck portion 314. The outer circumference of the friction nut 800 is slightly smaller than the circumference of the chamber 406. The portion of the engagement portion 314 that is inserted into the chamber 406 is threaded through the central bore 803 of the friction nut 800. The neck portion 314 and central bore 803 are forced into tight frictional engagement with one another so that they cannot be disengaged without significant forces acting on them. The bottom end of the friction nut abuts the step 312. The circumference of the friction nut 800 allows it to rotate within the chamber 406. The circumference of the neck portion 314 is dimensioned so that it can rotate within the opening 403. The neck portion 314 is long enough so that there is a small gap between the top surface 308 of the top saddle 325 and the bottom surface 409 of the compression nut 410. These dimensions permit the bottom saddle 325 to rotate relative to the compression nut 410.

In another embodiment, the top saddle 325 is fixedly attached to the compression nut 410 such that it does not rotate relative to the compression nut. In another embodiment, there is no top saddle and the compression nut directly contacts the stabilizer rod.

When the compression nut 410 is attached to the top saddle 325, the compression nut 410 is rotatingly coupled to the coupling element 115 by mating the outer threads of the compression nut 410 with the inner threads of the coupling element 115. The compression nut 410 is repeatedly rotated over a 360 degree rotational angle to lower the compression nut into the coupling element. The compression nut 410 is described herein as having outer threads that mate with inner threads on the opposed projections 310. As described below, this advantageously permits a thread configuration that prevents projections 310 from spreading apart from one another as the compression nut 410 is screwed into the coupling element 115. However, it should be appreciated that the compression nut 410 can be modified to have an annular shape with internal threads that mate with corresponding outer threads on the opposed projections 310.

As best shown in FIG. 4, the threads on the inner surfaces of the projections 310 of the coupling element 115 are tilted inwardly with respect to a horizontal axis (a horizontal axis is perpendicular to the axis A shown in FIGS. 3 and 4). The threads on the exterior of the compression nut 410 are correspondingly tilted. The tilted thread configuration causes the compression nut 410, when screwed into the coupling element 115, to prevent the projections 310 from spreading apart relative to one another. Rather, the compression nut 410 applies a radially inward (i.e., toward the axis A) force to the projections 310 as the compression nut 410 is screwed into the coupling element 115. This keeps the projections 410 from spreading apart while the compression nut 410 is screwed into the coupling element 115.

In addition, the threads are buttressed such that it requires less force to lower or tighten the compression nut 410 into the coupling element 115 and greater force to untighten or loosen the compression nut 410 relative to the coupling element 115. In this manner, it is unlikely that the compression nut will inadvertently loosen from the coupling element over time. This is advantageous, as the assembly can often be mounted in a vertebra for an extended period of time (such as several years) and it is undesirable for the compression nut to inadvertently loosen from the coupling element.

Other advantageous embodiments of the compression nut are shown in FIGS. 15A-17C. Bone fixation system shown in FIGS. 15A-15C shows a compression nut 710 with an external thread 712 that has both a load flank 713 and a stab flank 714 that are tilted inwardly in a downward direction toward the distal or bottom end 718 of the compression nut 710 and away from the proximal or top end 717 of the compression nut 710. Thread 712 has a load flank 713 that is sloped such that for a given cross-section of the thread through a longitudinal axis A of compression nut 710, a point on load flank 713 at a root 711 of thread 710 is closer to the top end 717 of compression nut 710 than a point on load flank 713 at a crest 716 of thread 712.

To define the angles of the thread surfaces, plane B normal to longitudinal axis A is also shown. Angle α represents the angle measured clockwise from thread root 711 at plane B to stab flank surface 714. Load flank 713 is at a downward curved slope from thread root 711 to thread crest 716. Stated somewhat differently, load flank 713 forms a concave shape from thread root 711 the thread crest 716 in which thread root 711 is closer to top end 717 of compression nut 710 than is thread crest 716.

Coupling element 615 has an internal thread 612 that complements and mates with external thread 712 of compression nut 710. When measured clockwise from normal plane B to clearance flank surface 614, clearance flank 614 of internal thread 612 forms an angle that is of substantially the same magnitude as angle α. Stab flank 613 forms a convex shape from thread root 611 to thread crest 616. Thus, thread 712 of compression nut 710 and thread 612 of coupling element 615 are engaged when compression nut 710 is threadedly engaged within internal bore 605 of coupling element 615. Angle α can be between about −1° and about −40°. In accordance with various embodiments, angle α can be about −1°, about −5°, about −10°, about −15°, about −20°, about −25°, about −30°, about −35°, or about −40°.

The thread configuration shown in FIGS. 15A-15C causes the compression nut 710, when screwed into the coupling element 615, to prevent the projections 610 from spreading apart relative to one another. Rather, the compression nut 710 applies a radially inward (i.e., toward the axis A) force to the projections 610 as the compression nut 710 is screwed into the coupling element 615. This keeps the projections 610 from spreading apart while the compression nut 710 is screwed into the coupling element 615.

More specifically, the way in which the thread geometry of the embodiment shown in FIGS. 15A-15C prevents splaying is based on the formation of a crest/root interference fit. Any outward, splaying force on the arms 610 of the coupling element 615 manifests itself in a force having two components: (1) a lateral component; and (2) an upward component. The upward component of the force causes crest 616 of thread 612 of coupling element 615 to arc up resulting in crest 616 getting lodged into root 711 of thread 712 of compression nut 710. The lateral component causes clearance flank 614 of thread 612 of coupling element 615 to push laterally against stab flank 714 of thread 712 of compression nut 710. Due to the angle of the stab flank 714, this lateral force pulls thread 712 downward into an interference fit between crest 716 and root 611. This dual-interference fit mechanism provides increased anti-splaying properties. Need to describe items 611 and 613 shown in FIGS. 15A-15C.

FIG. 16 shows a compression nut 910 with threads 912 that are tilted inwardly in the same manner as those in FIG. 12. Thread 912 of compression nut 410 is similar to thread 712 of compression nut 710, except that load flank 913 of thread 912 is linear rather than curved or concave and thread crest 916 forms a point. As with the embodiment shown in FIGS. 15A-15C, coupling element 815 has an internal thread 812 that complements and mates with external thread 912 of compression nut 10. Stab flank 813 of thread 812 is also linear rather than curved or convex.

FIGS. 17A-17C show another embodiment of a compression nut 1410 and corresponding coupling element 1315 with threads having a specific geometry. The internal threads 1312 of the coupling element include a forward-facing thread surface or load flank 1313 that is sloped so that, for a given cross-section of the thread 1312 through the longitudinal axis of the coupling element 1315, a point on the load flank surface 1313 at the crest 1316 of the thread 1312 is closer to the proximal or top of the coupling element 1315 than a point on the load flank surface 1313 at the root 1311 of the thread 1312.

External threads 1412 of the compression nut 1410 have a specific geometry that complements the geometry of the threads 1312 of the coupling element 1315. The rearward-facing or proximal facing thread surface (load flank surface 1413) is sloped or angled so that, for a given cross-section of the thread 1412 through the longitudinal axis of the compression nut 1410, a point on the load flank surface 1413 at the root 1411 of the thread 1412 is closer to the proximal end or top of the compression nut 1410 than a point on the load flank surface 1413 at the crest 1416 of the thread 1412, resulting in an angle α measured clockwise from a normal plane, such as plane Z, to the load flank surface 1413. Angle α can be between about −1° and about −40°. In accordance with various embodiments, angle α can be about −1°, about −5°, about −10°, about −15°, about −20°, about −25°, about −30°, about −35°, about −37°, or about −40°. The forward-facing or distal facing thread surface (stab flank surface 1414) is sloped or angled at an angle β measured clockwise from normal plane Z′, to the stab flank surface 1414. Plane Z′ is parallel to plane Z. Angle β can be between about −1° and about −40°. In accordance with various embodiments, angle β can be about −1°, about −5°, about −10°, about −15°, about −20°, about −25°, about −30°, about −35°, about −37°, or about −40°.

The way in which the thread geometry shown in FIGS. 17A-17C prevents splaying is based on the formation of a crest/root interference fit. Any outward, splaying force on the projections 1310 of the coupling element 1315 manifests itself in a force having two components: (1) a lateral component; and (2) an upward component. The upward component of the force causes the crest of the internal thread to arc up resulting in the crest of the internal thread getting lodged into the root of the external thread. The lateral component causes the rearward-facing or clearance flank of the internal thread to push laterally against the forward-facing or clearance flank of the external thread. Due to the angle of the clearance flank, this lateral force pulls the fastener thread downward into an interference fit between the crest of the external thread and the root of the internal thread. This dual-interference fit mechanism improves anti-splaying properties.

The thread geometry shown in FIGS. 17A-17C is also directed to the issue of torque vs. rotational displacement of the compression nut 1410. It can be desirable to stiffen the response of the fastener to torque in order to increase the amount of torque required to unscrew the compression nut. An improved response results from increasing the contact surface area, and consequently the frictional forces, between the internal threads 1312 of the coupling element 1315 and external threads 1412 of the compression nut 1410 in the manner shown in FIGS. 17A-17C. Specifically, thread 1412 has three main sides: a proximal side 1466, a lateral side 1467, and a distal side 1468. These three main sides of thread 1412 make contact with thread 1312, which has a corresponding proximal side 1366, lateral side 1367 and distal side 1368. This results in an increase in contact surface area of approximately 20% over a buttress, v-shaped, or reverse-angle thread having only two main sides.

In one embodiment, the various components of the assembly are manufactured of an inert material, such as, for example, stainless steel or titanium.

In other embodiments, the seat 327 is formed of one or more inclined or slanted surfaces. The seat 327 can be formed of an annular surface such that the seat 327 is generally conical or the seat 327 can be formed of three or more flat surfaces, such that the seat is pyramidal.

In another embodiment, as shown in FIGS. 20 a, 20 b, and 20 c, the seat 327 is conically shaped. During assembly of the device, the conically-shaped seat 327 supports the rounded head 210 of the fixation element 110. It should be appreciated that in other embodiments the head 210 can be other shapes. The rounded head 210 abuts against the conically-shaped seat 327 in the bottom of the coupling element 115, as shown in the cross-sectional view of FIG. 20 b. The head portion 210 contacts the conically-shaped seat 327 only along an annular contact region, which can be in the form of a contact circle 2010 as seen in FIGS. 20 b and 20 c. Because the seat 327 is conically shaped, the rounded head 210 can be rotated within the seat 327 to move the axis of the shank portion 205 to a desired orientation relative to the coupling element 115 and thereby provide a poly-axial configuration.

With the fixation element 110 seated in the coupling element 115, an operator can position the assembly relative to a bone structure such as a vertebra. When the device is fully assembled, the operator can couple a drive device (such as an Allen wrench) to the drive cavity 215 in the head 210 and rotate the fixation element 110 to drive the shank portion 205 into a vertebra or other bone structure.

After the bottom saddle 320, the rod 120, and the top saddle 325 are loaded into the coupling element 115, the compression nut 410 can be threaded downward. As the compression nut 410 is threaded downward, the downward force of the compression nut 410 is transferred to the bottom saddle 320 via the top saddle 325 and the rod 120. This causes the bottom saddle 320 to also move downward so as to press downward against the head 210 of the fixation element 110. The rounded head 210 is thereby wedged downward into the conically-shaped seat 327 in a fixed orientation. The force exerted by the rounded head 210 along the contact circle 2010 can optionally cause an indentation, such as a slight indentation along contact circle 2010. If present, the slight indentation along contact circle 2010 creates increased friction between the head 210 and the seat 327 which provides a secure fit between the rounded head 210 and the coupling element 115.

In this manner, the position of the fixation element 110 relative to the coupling element 115 is fixed. That is, the head 210 of the fixation element 110 is wedged downward into the conically-shaped seat 327 of the coupling element 115 with a force sufficient to lock the position of the head 210 relative to the coupling element 115. This can occur whether or not the head forms an indentation in the seat. The compression nut 410 provides a downward force that locks the relative positions of the elongated rod 120, saddles 320, 325, coupling element 115, and fixation element 110.

FIGS. 21 a, 21 b, and 21 c show the seat 327 with a first conically shaped surface 2115 and a second conically shaped surface 2120. The second conically shaped surface 2120 has a pitch angle β from the horizontal that is greater than the pitch angle α of the first conically shaped surface. The rounded head 210 abuts against the first conically shaped surface 2115 and the second conically shaped surface 2120 in the bottom of the coupling element 115, as shown in the cross-sectional view of FIG. 21 b. The head portion 210 contacts the conically-shaped seat 327 along a first contact region, such as a contact circle 2125, and a second contact region, such as a circle 2130, as seen in FIGS. 21 b and 21 c. The seat 327 in this embodiment allows the rounded head 210 to be rotated within the seat 327 so that the axis of the shank portion 205 can be moved to a desired orientation relative to the coupling element 115 and thereby provide a poly-axial configuration.

As the compression nut 410 is threaded downward, the downward force of the compression nut 410 is transferred to the head 210 of the fixation element 110. The rounded head 210 is thereby wedged downward into the seat 327 in a fixed orientation. The force exerted by the rounded head along the first contact circle 2125 and the second contact circle 2130 can optionally cause an indentation, such as a slight indentation. The slight indentations along the first contact circle 2125 and the second contact circle 2130 create a stronger friction fit between the rounded head 210 and the coupling element 115. It should also be appreciated that there may be multiple conically shaped surfaces.

In FIGS. 22, 23 a, 23 b, and 24 the seat 327 is pyramid shaped instead of conically-shaped. The pyramid-shaped seat in FIG. 22 has three slanted faces 2240, 2245, 2250. It should be appreciated that the pyramid-shaped seat 327 may have more than three faces. For example, FIGS. 23 a and 23 b depict the pyramid-shaped seat 327 with four faces 2340, 2345, 2350, 2355. The rounded head 210 abuts against the pyramid-shaped seat 327 in the bottom of the coupling element 115. The rounded head portion 210 contacts the slanted faces of the three-sided pyramid-shaped seat at contact points 2251 as seen in FIG. 22. In FIGS. 23 a and 23 b, the rounded head portion 210 will contact the slanted faces of the three-sided pyramid-shaped seat at contact points 2360. The rounded head 210 can be rotated within the seat 327 to move the axis of the shank portion 205 to a desired orientation relative to the coupling element 115 and thereby provide a poly-axial configuration.

As the compression nut 410 is threaded downward, the downward force of the compression nut 410 is transferred to the head 210 of the fixation element 110. The rounded head 210 is thereby wedged downward into the pyramid shaped seat 327 in a fixed orientation. The force exerted by the rounded head at the contact points can cause a slight indentation. The slight indentations at the contact points create a stronger friction fit between the rounded head 210 and the coupling element 115.

Also, each of the slanted surface of the pyramid may also have a variable pitch as seen in FIG. 24. FIG. 24 depicts each face having two variable pitches and each face having two contact points. In this example, the rounded head would contact each face at two contact points 2410. In this embodiment, there are eight contact points altogether only two of which are numbered. It is also contemplated that each face may have multiple pitches.

As the compression nut 410 is threaded downward, the downward force of the compression nut 410 is transferred to the head 210 of the fixation element 110. The rounded head 210 is thereby wedged downward into the pyramid shaped seat 327 with variable-pitched faces in a fixed orientation. The force exerted by the rounded head at the contact points can cause a slight indentation. The slight indentations at the contact points create a stronger friction fit.

The various embodiments of top saddles, compression nut threading geometries, and coupling element threading geometries are described herein with respect to polyaxial pedicle screws. However, it should be appreciated that they can be used with monoaxial pedicle screws as well.

Although embodiments of various methods and devices are described herein in detail with reference to certain versions, it should be appreciated that other versions, embodiments, methods of use, and combinations thereof are also possible. Therefore the spirit and scope of the appended claims should not be limited to the description of the embodiments contained herein. 

1. A bone stabilizer assembly, comprising: a fixation element adapted to engage a bone and having a head portion and shank portion; a coupling element having an internal bore sized to receive the shank portion of the fixation element and a pyramid-shaped seat for supporting the head portion of the fixation element, the coupling element adapted to receive a stabilizer rod; and a compression nut engagable with the coupling element, the compression nut adapted to rotatingly move distally into the coupling element to translate a force to the head portion through the rod and the saddle such that the head portion is forced against the seat of the coupling element to prevent relative movement between the fixation element and the coupling element.
 2. The bone stabilizer assembly of claim 1, wherein the head portion is substantially spherical in shape.
 3. The bone stabilizer assembly of claim 1, wherein the head portion causes an indentation in the seat where the head portion is forced against the pyramid-shaped seat.
 4. The bone stabilizer assembly of claim 1, wherein the pyramid shaped-seat has at least three slanted faces.
 5. The bone stabilizer assembly of claim 4, wherein each face has a first and second pitch.
 6. The bone stabilizer assembly of claim 5, wherein the pitch angle of the first pitch is greater than the pitch angle of the second pitch.
 7. The bone stabilizer of claim 1, further comprising a saddle movably mounted in the coupling element below the stabilizer rod when the stabilizer rod is in the coupling element. 